Finite Element Analysis of Hydraulic Clipping Machine Shear Platform Dased on ANSYS

Hai Lin Wang; Yi Hua Sun; Ming Bo Li; Gao Lin; Yun Qi Feng; Shi Li Wu; Cai Hua Huang; Jian Chen

doi:10.4028/www.scientific.net/AMR.945-949.190

Paper Titles

Finite Element Analysis and Optimization for the Structure of NC Forming Machine
p.166

Mechanical Characteristics Analysis and Design Optimization of the Derrick
p.174

3D Magnetic Field and Temperature Rise Analysis of Dry-Type Transformer Based on Finite Element Method
p.181

The 3D Finite Element Analysis of Magnetic Controlled Reactor
p.185

Finite Element Analysis of Hydraulic Clipping Machine Shear Platform Dased on ANSYS
p.190

The Simulation and Design of a Kind of Fitness Ball Testing Machine
p.194

The Numerical Simulation of the Lateral Inhomogeneous Deformation of the Permafrost Subgrade
p.198

The Virtual Assembly Simulation and Optimization Design on Single Screw Pump of Offshore Petroleum Well Cementing LADS Device
p.203

Research of Armored Anti-Riot Vehicles Repair Based on Virtual Maintenance Technology
p.209

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 945-949Finite Element Analysis of Hydraulic Clipping...

Finite Element Analysis of Hydraulic Clipping Machine Shear Platform Dased on ANSYS

Abstract:

Q43Y-85D type crocodile hydraulic clipping machine was taken as research object to optimization design. A finite element model for clipping machine was built using shell unit as fundamental unit. ANSYS12.0 finite element method was used to analyze the deformation and stress distribution of the shear platform model of hydraulic clipping machine. The result showed that the maximum equivalent stress at the dangerous area was 368.162 MPa and the maximum elastic strain was 0.1814×10^-2 mm. After the structural optimization design, it was found that the maximum equivalent stress decreased to 186.238 MPa which did not exceed the material’s yield limitation 215 MPa and the maximum elastic strain decreased to 0.919×10^-3 mm which satisfied the requirement of stiffness.

You might also be interested in these eBooks

Advances in Manufacturing Science and Engineering V

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 945-949)

Pages:

190-193

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.945-949.190

Citation:

Cite this paper

Online since:

June 2014

Authors:

Hai Lin Wang, Yi Hua Sun*, Ming Bo Li, Gao Lin, Yun Qi Feng, Shi Li Wu, Cai Hua Huang, Jian Chen

Keywords:

ANSYS Finite Element Analysis, Shear Platform, Shell Unit, Structure Optimization

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] X.Y. Zhang, J. Xiong, X. Hao, R.M. Lai: Mechanical Science and Technology for Aerospace Engineering Vol. 12 (2008), p.1602.

Google Scholar

[2] X.C. Wu, Y.H. Li, Z.Y. H, J.C. Fan, C.H. Li, X.M. Chen: Metallurgical Equiment Vol. 181 (2010), p.38.

Google Scholar

[3] F. Liu, W.M. Chen, N. Zhao: Machinery Design and Manufacture Vol. 9 (2012), p.78.

Google Scholar

[4] Z.J. Xie, Y. Sun, C. Li, W. Ni: Machinery and Electronics Vol. 1 (2010), p.65.

Google Scholar

[5] Z.D. Wu, X.G. Ma, X.M. You, W. Jiang, Q.G. Dong: Transaction of Shenyang University Vol. 4 (2008), p.80.

Google Scholar

[6] M.O. Tokhi, Z. Mohamed: Journal of Low Frequency Noise Vibration and Active Control Vol. 2 (1999), p.63.

Google Scholar

[7] Y.C. Liu, J.S. Solecki, E.D. Underwood: Progress in Structural Engineering and Materials Vol. 3 (1998), p.351.

Google Scholar

[8] Information on http: /www. Simwe. com.

Google Scholar

[9] Q. Wu, H.Q. Qiu, Y. Zheng: Transaction of the China Welding Institution Vol. 7 (2010), p.22.

Google Scholar

[10] J. Awrejcewicz, L. Kurpa, A. Osetrov: Angew. Math. Mech Vol. 6 (2011), p.458.

Google Scholar